CONVECTIVE-REACTIVE PROTON-<sup>12</sup>C COMBUSTION IN SAKURAI'S OBJECT (V4334 SAGITTARII) AND IMPLICATIONS FOR THE EVOLUTION AND YIELDS FROM THE FIRST GENERATIONS OF STARS

Herwig, Falk; Pignatari, M.; Woodward, Paul R.; Porter, David H.; Rockefeller, Gabriel; Fryer, Chris L.; Bennett, Michael; Hirschi, Raphaël

doi:10.1088/0004-637x/727/2/89

Cited by 217 publications

(354 citation statements)

References 90 publications

(93 reference statements)

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“…This trend follows that of the neutron exposure in the interpulse (Table 4). The enrichments achieved are not enough to explain the typical observation for AGB stars of roughly solar metallcity that [Ba/Fe]∼1, hence, this model may be relevant only for specific applications, e.g., the production of 86 Kr (Raut et al 2013) or, potentially, the composition of Sakurai's Object, as an alternative to the proton-ingestion episode (Herwig et al 2011). …”

Section: Comparison Of the Results From Setmentioning

confidence: 95%

Partial mixing and the formation of 13C pockets in AGB stars: effects on the s-process elements

Buntain

Doherty

Lugaro

et al. 2017

Monthly Notices of the Royal Astronomical Society

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The production of the elements heavier than iron via slow neutron captures (the s process) is a main feature of the contribution of asymptotic giant branch (AGB) stars of low mass (< 5 Msun) to the chemistry of the cosmos. However, our understanding of the main neutron source, the 13 C(α,n) 16 O reaction, is still incomplete. It is commonly assumed that in AGB stars mixing beyond convective borders drives the formation of 13 C pockets. However, there is no agreement on the nature of such mixing and free parameters are present. By means of a parametric model we investigate the impact of different mixing functions on the final s-process abundances in low-mass AGB models. Typically, changing the shape of the mixing function or the mass extent of the region affected by the mixing produce the same results. Variations in the relative abundance distribution of the three s-process peaks (Sr, Ba, and Pb) are generally within +/-0.2 dex, similar to the observational error bars. We conclude that other stellar uncertainties -the effect of rotation and of overshoot into the C-O core -play a more important role than the details of the mixing function. The exception is at low metallicity, where the Pb abundance is significantly affected. In relation to the composition observed in stardust SiC grains from AGB stars, the models are relatively close to the data only when assuming the most extreme variation in the mixing profile.

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Section: Comparison Of the Results From Setmentioning

confidence: 95%

Partial mixing and the formation of 13C pockets in AGB stars: effects on the s-process elements

Buntain

Doherty

Lugaro

et al. 2017

Monthly Notices of the Royal Astronomical Society

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“…For a thorough discussion of these scenarios we refer to Jonsell et al (2006) and Lugaro et al (2009). Lugaro et al (2009) suggest a third speculative scenario in which r-and s-elements are both formed in low-mass extremely metalpoor AGB stars ([Fe/H] < −3), that may be able to produce very high densities of free neutrons when protons are ingested in the region of the He-flash (Campbell 2007;Campbell & Lattanzio 2008;Herwig et al 2011;Reifarth et al 2014). …”

Section: Comparison With Previous Resultsmentioning

confidence: 99%

Carbon-enhanced metal-poor stars: a window on AGB nucleosynthesis and binary evolution

Abate

Pols

Izzard

et al. 2015

A&A

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Many of the carbon-enhanced metal-poor (CEMP) stars that we observe in the Galactic halo are found in binary systems and show enhanced abundances of elements produced by the slow neutron-capture process (s-elements). The origin of the peculiar chemical abundances of these CEMP-s stars is believed to be accretion in the past of enriched material from a primary star in the asymptotic giant branch (AGB) phase of its evolution. We investigate the mechanism of mass transfer and the process of nucleosynthesis in low-metallicity AGB stars by modelling the binary systems in which the observed CEMP-s stars were formed. For this purpose we compare a sample of 67 CEMP-s stars with a grid of binary stars generated by our binary evolution and nucleosynthesis model. We classify our sample CEMP-s stars in three groups based on the observed abundance of europium. In CEMP-s/r stars the europium-toiron ratio is more than ten times higher than in the Sun, whereas it is lower than this threshold in CEMP-s/nr stars. No measurement of europium is currently available for CEMP-s/ur stars. On average our models reproduce the abundances observed in CEMP-s/nr stars well, whereas in CEMP-s/r stars and CEMP-s/ur stars the abundances of the light-s elements (strontium, yttrium, zirconium) are systematically overpredicted by our models, and in CEMP-s/r stars the abundances of the heavy-s elements (barium, lanthanum) are underestimated. In all stars our modelled abundances of sodium overestimate the observations. This discrepancy is reduced only in models that underestimate the abundances of most of the s-elements. Furthermore, the abundance of lead is underpredicted in most of our model stars, independent of the metallicity. These results point to the limitations of our AGB nucleosynthesis model, particularly in the predictions of the element-to-element ratios. In our models CEMP-s stars are typically formed in wide systems with periods above 10 000 days, while most of the observed CEMP-s stars are found in relatively close orbits with periods below 5000 days. This evidence suggests that either the sample of CEMP-s binary stars with known orbital parameters is biased towards short periods or that our wind mass-transfer model requires more efficient accretion in close orbits.

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“…Nuclear energy production increases within minutes ( Fig. 1), and the burning of H creates a split in the He-shell, similar to Herwig et al (2011). 3D simulations are only starting to investigate this process with the necessary numerical effort (Herwig et al 2014), but already show that violent, global instabilities are possible.…”

Section: D Stellar Evolution Modelmentioning

confidence: 86%

“…The [Na/Mg] ratio could be as small as ≈ −0.3 dex in these conditions. But the presence Fegroup n-capture seeds, or even a too high neutron exposure with Pop III initial abundance, would lead to an efficient production of trans-iron elements with the i-process abundance signature, leading not to CEMP-no but to CEMP-i (or CEMP-r/s) star abundance signatures (Dardelet et al 2014;Herwig et al 2011;Hampel et al 2016). …”

Section: Nucleosynthesis Calculationsmentioning

confidence: 99%

Pop III i-process nucleosynthesis and the elemental abundances of SMSS J0313−6708 and the most iron-poor stars

Clarkson

Herwig

Pignatari

2017

Monthly Notices of the Royal Astronomical Society: Letters

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We have investigated a highly energetic H-ingestion event during shell He burning leading to H-burning luminosities of log(L H /L ) ∼ 13 in a 45M Pop III massive stellar model. In order to track the nucleosynthesis which may occur in such an event, we run a series of single-zone nucleosynthesis models for typical conditions found in the stellar evolution model. Such nucleosynthesis conditions may lead to i-process neutron densities of up to ∼ 10 13 cm −3 . The resulting simulation abundance pattern, where Mg comes from He burning and Ca from the i process, agrees with the general observed pattern of the most iron-poor star currently known, SMSS J031300.36-670839.3. However, Na is also efficiently produced in these i process conditions, and the prediction exceeds observations by ∼ 2.5dex. While this probably rules out this model for SMSS J031300.36-670839.3, the typical i-process signature of combined He burning and i process of higher than solar [Na/Mg], [Mg/Al] and low [Ca/Mg] is reproducing abundance features of the two next most iron-poor stars HE 1017-5240 and HE 1327-2326 very well. The i process does not reach Fe which would have to come from a low level of additional enrichment. i process in hyper-metal poor or Pop III massive stars may be able to explain certain abundance patterns observed in some of the most-metal poor CEMP-no stars.

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CONVECTIVE-REACTIVE PROTON-¹²C COMBUSTION IN SAKURAI'S OBJECT (V4334 SAGITTARII) AND IMPLICATIONS FOR THE EVOLUTION AND YIELDS FROM THE FIRST GENERATIONS OF STARS

Cited by 217 publications

References 90 publications

Partial mixing and the formation of 13C pockets in AGB stars: effects on the s-process elements

Partial mixing and the formation of 13C pockets in AGB stars: effects on the s-process elements

Carbon-enhanced metal-poor stars: a window on AGB nucleosynthesis and binary evolution

Pop III i-process nucleosynthesis and the elemental abundances of SMSS J0313−6708 and the most iron-poor stars

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CONVECTIVE-REACTIVE PROTON-12C COMBUSTION IN SAKURAI'S OBJECT (V4334 SAGITTARII) AND IMPLICATIONS FOR THE EVOLUTION AND YIELDS FROM THE FIRST GENERATIONS OF STARS

Cited by 217 publications

References 90 publications

Partial mixing and the formation of 13C pockets in AGB stars: effects on the s-process elements

Partial mixing and the formation of 13C pockets in AGB stars: effects on the s-process elements

Carbon-enhanced metal-poor stars: a window on AGB nucleosynthesis and binary evolution

Pop III i-process nucleosynthesis and the elemental abundances of SMSS J0313−6708 and the most iron-poor stars

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CONVECTIVE-REACTIVE PROTON-¹²C COMBUSTION IN SAKURAI'S OBJECT (V4334 SAGITTARII) AND IMPLICATIONS FOR THE EVOLUTION AND YIELDS FROM THE FIRST GENERATIONS OF STARS